SI5100-H-GL Silicon Laboratories Inc, SI5100-H-GL Datasheet - Page 15

SI5100-H-GL

Manufacturer Part Number

SI5100-H-GL

Description

IC TXRX SONET/SDH LP HS 195PBGA

Manufacturer

Silicon Laboratories Inc

Series

SiPHY®r

Type

Transceiverr

Datasheet

1.SI5100-H-GL.pdf (40 pages)

Specifications of SI5100-H-GL

Package / Case

196-BGA

Number Of Drivers/receivers

1/1

Protocol

SONET/SDH

Voltage - Supply

1.71 V ~ 1.89 V

Mounting Type

Surface Mount

Product

PHY

Supply Voltage (max)

1.89 V, 3.47 V

Supply Voltage (min)

1.71 V

Supply Current

0.83 A

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 20 C

Mounting Style

SMD/SMT

Maximum Power Dissipation

1600 mW

Number Of Channels

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Available stocks

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Part Number

Manufacturer

Quantity

Price

Company:

BOSTOCK HK LIMITED

Part Number:

SI5100-H-GL

Manufacturer:

Silicon Laboratories Inc

Quantity:

10 000

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5.2.3. Slice Level Adjustment

The limiting amplifier allows adjustment of the 0/1

decision threshold, or slice level, to allow optimization of

bit-error-rates (BER) for demanding applications, such

as long-haul links. The Si5100 provides two different

modes of slice level adjustment: Absolute slice mode

and proportional slice mode. The mode is selected

using the SLICEMODE input.

In either mode, the slice level is set by applying a dc

voltage to the SLICELVL input. The mapping of the

voltage on the SLICELVL pin to the 0/1 decision

threshold voltage (or slice voltage) depends on the

selected mode of operation.

The SLICELVL mapping for absolute slice mode

(SLICEMODE = 0) is given in Figure 6. The linear

region of this curve can be approximated by the

following equation:

where V

RXDIN input, V

SLICELVL pin, and VREF is the reference voltage

provided by the Si5100 on the VREF output pin

(nominally 1.25 V).

The SLICELVL mapping for proportional slice mode

(SLICEMODE = 1) is given in Figure 7 on page 18. The

linear region of this curve can be approximated by the

following equation:

where V

RXDIN input; V

SLICELVL pin; VREF is the reference voltage provided

by the Si5100 on the VREF output pin, and V

is the peak-to-peak voltage level of the receive data

signal applied to the RXDIN input.

The slice level adjustment function can be disabled by

tieing the SLICELVL input the VREF. When slice level

adjustment is disabled, the effective slice level is set to

0 mV relative to internally biased input common mode

voltage for RXDIN.

5.3. Clock and Data Recovery (CDR)

The Si5100 uses an integrated CDR to recover clock

and data from a non-return to zero (NRZ) signal input on

RXDIN. The recovered clock is used to regenerate the

incoming data by sampling the output of the limiting

amplifier at the center of the NRZ bit period.

LEVEL

(

≈

LEVEL

(

RXDIN PP

(

SLICELVL

is the effective slice level referred to the

SLICELVL

≈

(

[

(

)

SLICELVL

Equation 6

Equation 7

0.95

–

(

is the voltage applied to the

VREF 0.4

)

]

–

[

0.03

(

VREF 0.4

)

RXDIN PP

0.375

)

(

) 0.005

RXDIN(PP)

–

)

]

Rev. 1.4

5.3.1. Sample Phase Adjustment

introduced by the transmission medium, it may be

desirable to recover data by sampling at a point that is

not at the center of the data eye. The Si5100 provides a

sample phase adjustment capability that allows

adjustment of the CDR sampling phase across the NRZ

data period. When sample phase adjustment is

enabled, the sampling instant used for data recovery

can be moved over a range of approximately ±22 ps

relative to the center of the incoming NRZ bit period.

The sample phase is set by applying a dc voltage to the

PHASEADJ input. The mapping of the voltage present

on the PHASEADJ input to the sample phase sampling

offset is given in Figure 8 on page 18. The linear region

of this curve can be approximated by the following

equation:

where Phase Offset is the sampling offset in

picoseconds from the center of the data eye; V

is the voltage applied to the PHASEADJ pin, and VREF

is the reference voltage provided by the Si5100 on the

VREF output pin (nominally 1.25 V). A positive phase

offset adjusts the sampling point to lead the default

sampling point (the aligned center of the data eye) and

a negative phase offset adjusts the sampling point to lag

the default sampling point.

Data recovery using a sampling phase offset is disabled

by tieing the PHASEADJ input to VREF. This forces a

phase offset of 0 ps to be used for data recovery.

5.3.2. Receiver Lock Detect

The Si5100 provides lock-detect circuitry that indicates

whether the PLL has achieved frequency lock with the

incoming data. This circuit compares the frequency of a

divided down version of the recovered clock with the

frequency of the supplied reference clock. The Si5100

uses either REFCLK or TXCLK16IN as the reference

clock input signal depending on the state of the

REFSEL input. If the (divided) recovered clock

frequency deviates from that of the reference clock by

more than the amount specified in Table 5 on page 10,

the CDR is declared out of lock, and the loss-of-lock

(RXLOL) pin is asserted. In this state, the CDR attempts

to reacquire lock with the incoming data stream. During

reacquisition, the recovered clock frequency (RXCLK1

and RXCLK2) drifts over a range of approximately

±1000 ppm relative to the supplied reference clock

unless LTR is asserted. The RXLOL output remains

asserted until the frequency of the (divided) recovered

clock differs from the reference clock frequency by less

Phase Offset 85 ps/V

applications where data eye

≈

Equation 8

(

PHASEADJ

–

(

distortions are

0.4 VREF

Si5100

PHASEADJ

)

SI5100-H-GL Silicon Laboratories Inc, SI5100-H-GL Datasheet - Page 15

SI5100-H-GL

Specifications of SI5100-H-GL

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